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Similar articles for PubMed (Select 16321421)

1.

In vitro dimensions and curvatures of human lenses.

Rosen AM, Denham DB, Fernandez V, Borja D, Ho A, Manns F, Parel JM, Augusteyn RC.

Vision Res. 2006 Mar;46(6-7):1002-9.

2.

Accommodation and presbyopia in the human eye. Changes in the anterior segment and crystalline lens with focus.

Koretz JF, Cook CA, Kaufman PL.

Invest Ophthalmol Vis Sci. 1997 Mar;38(3):569-78.

PMID:
9071209
3.
4.

Changes in the internal structure of the human crystalline lens with age and accommodation.

Dubbelman M, Van der Heijde GL, Weeber HA, Vrensen GF.

Vision Res. 2003 Oct;43(22):2363-75.

PMID:
12962993
6.

Change in shape of the aging human crystalline lens with accommodation.

Dubbelman M, Van der Heijde GL, Weeber HA.

Vision Res. 2005 Jan;45(1):117-32.

7.

Aging of the human crystalline lens and anterior segment.

Cook CA, Koretz JF, Pfahnl A, Hyun J, Kaufman PL.

Vision Res. 1994 Nov;34(22):2945-54.

PMID:
7975328
8.
9.

Age-related response of human lenses to stretching forces.

Pierscionek BK.

Exp Eye Res. 1995 Mar;60(3):325-32.

PMID:
7789412
10.

Changes in lens dimensions and refractive index with age and accommodation.

Jones CE, Atchison DA, Pope JM.

Optom Vis Sci. 2007 Oct;84(10):990-5.

PMID:
18049365
11.

Presbyopia and the optical changes in the human crystalline lens with age.

Glasser A, Campbell MC.

Vision Res. 1998 Jan;38(2):209-29.

12.

Comparison of the behavior of natural and refilled porcine lenses in a robotic lens stretcher.

Reilly MA, Hamilton PD, Perry G, Ravi N.

Exp Eye Res. 2009 Mar;88(3):483-94. doi: 10.1016/j.exer.2008.10.021. Epub 2008 Nov 11.

PMID:
19041865
13.

Aging of the human lens: changes in lens shape upon accommodation and with accommodative loss.

Koretz JF, Cook CA, Kaufman PL.

J Opt Soc Am A Opt Image Sci Vis. 2002 Jan;19(1):144-51.

PMID:
11778717
14.
15.

Slit-lamp studies of the rhesus monkey eye: II. Changes in crystalline lens shape, thickness and position during accommodation and aging.

Koretz JF, Bertasso AM, Neider MW, True-Gabelt BA, Kaufman PL.

Exp Eye Res. 1987 Aug;45(2):317-26.

PMID:
3653294
16.

Quantitative analysis of animal model lens anatomy: accommodative range is related to fiber structure and organization.

Kuszak JR, Mazurkiewicz M, Jison L, Madurski A, Ngando A, Zoltoski RK.

Vet Ophthalmol. 2006 Sep-Oct;9(5):266-80.

PMID:
16939454
17.

Constant volume of the human lens and decrease in surface area of the capsular bag during accommodation: an MRI and Scheimpflug study.

Hermans EA, Pouwels PJ, Dubbelman M, Kuijer JP, van der Heijde RG, Heethaar RM.

Invest Ophthalmol Vis Sci. 2009 Jan;50(1):281-9. doi: 10.1167/iovs.08-2124. Epub 2008 Aug 1. Erratum in: Invest Ophthalmol Vis Sci. 2009 Jun;50(6):2625.

PMID:
18676625
18.

Age-related changes in human ciliary muscle and lens: a magnetic resonance imaging study.

Strenk SA, Semmlow JL, Strenk LM, Munoz P, Gronlund-Jacob J, DeMarco JK.

Invest Ophthalmol Vis Sci. 1999 May;40(6):1162-9.

PMID:
10235549
19.

Presbyopia, accommodation, and the mature catenary.

Coleman DJ, Fish SK.

Ophthalmology. 2001 Sep;108(9):1544-51.

PMID:
11535447
20.

Changes in ocular dimensions and refraction with accommodation.

Garner LF, Yap MK.

Ophthalmic Physiol Opt. 1997 Jan;17(1):12-7.

PMID:
9135807
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